Insecticidal protein fragments

ABSTRACT

The  Bacillus thuringiensis  var. kurstaki HD-73 crystal protein gene was cloned into pBR322.  E. coli  cells harboring this recombinant plasmid produced a 130 kD protoxin that was toxic to  Manduca sexta  (tobacco hornworm) larvae. Plasmids having the 3′-end of the protoxin gene deleted where also constructed.  E. coli  cells harboring these deleted plasmids produced an active, soluble 68 kD toxin, provided that the 3′-deletion had not removed sequences encoding the 68 kD toxin. The invention provides methods to produce 68 kD toxin protein by constructing partial protoxin genes encoding the toxin followed by expression of the genes in living cells. Useful plasmids and cells are also provided.

CROSS REFERENCE TO A RELATED APPLICATION

This application is a divisional of U.S. Ser. No. 06/617,321 filed Jun.4, 1984, now U.S. Pat. No. 6,114,138 which is a Continuation-In-Part ofapplication Ser. No. 06/535,354, filed Sep. 24, 1983.

FIELD

The present invention is in the fields of genetic engineering andbacterial bio-affecting compositions, especially those derived from thegenus Bacillus.

BACKGROUND

The following are publications disclosing background information relatedto the present invention: G. A. Held et al. (1982) Proc. Natl. Acad.Sci. USA 77:6065-6069; A. Klier et al. (1982) EMBO J. 1:791-799; A.Klier et al. (1983) Nucl. Acids Res. 11:3973-3987; H. E. Schnepf and H.R. Whitely (1981) Proc. Natl. Acad. Sci. USA 78:2893-2897; H. E. Schnepfand X. R. Whitely, European Pat. application 63,949; H. R. Whitely etal. (1982) Molecular Cloning and Gene Regulation in Bacilli, eds: A. T.Ganesan et al., pp. 131-144; H. C. Wong et al. (1983) J. Biol. Chem.258:1960-1967. R. M. Faust et al. (1974) J. Invertebr. Pathol.24:365-373, T. Yamamoto and R. E. McLaughlin (1981) Biochem. Biophys.Res. Commun. 103:414-421, and H. E. Huber and P. Luthy (1981) inPathogenesis of Invertebrate Microbiol. Diseases, ed.: E. W. Davidson,pp. 209-234, report production of activated toxin from crystal proteinprotoxin. None of the above publications report that partial protoxingenes when transcribed and translated produced insecticidal proteins asdisclosed herein. These publications are discussed in the Backgroundsection on Molecular Biology. S. Chang (1983) Trends Biotechnol.1:100-101, reported that the DNA sequence of the HD-1 gene had beenpublicly presented, (ref. 5 therein), and that the HD-1 toxin moietyresides in the amino-terminal 68kD peptide. M. J. Adang and J. D. Kemp,U.S. patent application Ser. No. 535,354, which is hereby incorporatedby reference, described a plasmid, p123/58-10 therein, pBt73-10 herein,containing a partial protexin gene that, when transformed into E. coli,directed synthesis of an Insecticidal protein. M. J. Adang and J. D.Kemp, supra, and R. F. Barker and J. D. Kemp, U.S. patent applicationSer. No. 553,786, which is hereby incorporated by reference, both teachexpression of the same pBt73-10 partial protoxin structural gene inplants cells. Detailed comparisons of results disclosed as part of thepresent application with published reports are also detailed herein inthe Examples, especially Example 5.

Chemistry

Bacillus thuringiensis, a species of bacteria closely related to B.cereus, forms a proteinacious crystalline inclusion during sporulation.This crystal is parasporal, forming within the cell at the end oppositefrom the developing spore. The crystal protein, often referred to as theδ-endotoxin, has two forms: a nontoxic protoxin of approximate molecularweight (MW) of 130 kilodaltons (kD), and a toxin having an approx. MW of68 kD. The crystal contains the protoxin protein which is activated inthe gut of larvae of a number of insect species. M. J. Klowden et al.(1983) Appl. Envir. Microbiol. 46:312-315, have shown solubilizedprotoxin from B. thuringiensis var. israelensis is toxic to Aedesaegypti adults. A 65kD “mosquito toxin” seems to be isolatable withoutan activation step from crystals of HD-1 (T. Yamamoto and R. E.McLaughlin (1981) Biochem. Biophys. Res. Commun. 103:414-421). Duringactivation, the protoxin is cleaved into two polypeptides, one or bothof which are toxic. In vivo, the crystal is activated by beingsolubilized and converted to toxic form by the alkalinity and proteasesof the insect gut.

In vitro the protoxin may be solubilized by extremely high pH (e.g. pH12), by reducing agents under moderately basic conditions (e.g. pH 10),or by strong denaturants (guanidium, urea) under neutral conditions (pH7). Once solubilized, the crystal protein may be activated in vitro bythe action of the protease such as trypsin (R. M. Faust et al. (1974) J.Invertebr. Pathol. 24:365-373). Activation of the protoxin has beenreviewed by H. E. Huber and P. Luthy (1981) in Pathogenesis ofInvertebrate Microbiol. Diseases, ed.: E. W. Davidson, pp. 209-234. Thecrystal protein is reported to be antigenically related to proteinswithin both the spore coat and the vegetative cell wall. Carbohydrate isnot involved in the toxic properties of the protein.

Toxicology

B. thuringiensis and its crystalline end in are useful because thecrystal protein is an insecticidal protein known to be poisonous to thelarvae of over a hundred of species of insects, most commonly those fromthe orders Lepidoptera and Diptera. Insects susceptible to the action ofthe B. thuringiensis crystal protein include, but need not be limitedto, those listed in Table 1. Many of these insect species areeconomically important pests. Plants which can be protected byapplication of the crystal protein include, but need not be limited to,those listed in Table 2. Different varieties of B. thuringiensis, whichinclude, but need not be limited to, those listed in Table 3, havedifferent host ranges (R. M. Faust et al. (1982) in Genetic Engineeringin the Plant Sciences, ed. N. J. Panapolous, pp. 225-254); this probablyreflects the toxicity of a given crystal protein in a particular host.The crystal protein is highly specific to insects; in over two decadesof commercial application of sporulated B. thuringiensis cells to cropsand ornamentals there has been no known case of effects to plants ornoninsect animals. The efficacy and safety of the endotoxin have beenreviewed by R. M. Faust et al., supra. Other useful reviews includethose by P. G. Fast (1981) in Microbial Control of Pests and PlantDiseases, 1970-1980, ed.: H. D. Burges, pp. 223-248, and H. E. Huber andP. Luthy (1981) in Pathogenesis of Invertebrate Microbial Diseases, ed.:E. W. Davidson, pp. 209-234.

Molecular Biology

The crystal protein gene usually can be found on one of several largeplasmids that have been found in Bacillus thuringiensis, though in somestrains it may be located on the chromosome (J. W. Kronstad et al.(1983) J. Bacteriol. 154:419-428; J. M. Gonzalez Jr. et al. (1981)Plasmid 5:31-365). Crystal protein genes have been cloned into plasmidsthat can grow in E. coli by several laboratories.

Whiteley's group (H. R. Whiteley et al. (1982) in Molecular Cloning andGene Regulation in Bacilli, eds.: A. T. Ganesan et al., pp. 131-144, H.E. Schnepf and H. R. Whiteley (1981) Proc. Natl. Acad. Sci. USA78:2893-2897, and European Pat. application 63,949) reported the cloningof the protoxin gene from B. thuringiensis var. kurstaki strainsHD-1-Dipel and HD-73, using the enzymes Sau3AI (under partial digestconditions) and BglII, respectively, to insert large gene-bearingfragments having approximate sizes of 12 kbp and 16 kbp into the BamHIsite of the E. coli plasmid vector pBR322. The HD-1 crystal protein genewas observed to be contained within a 6.6 kilobase pair (kbp) HindIIIfragment. Crystal protein which was toxic to larvae, immunologicallyidentifiable, and the same size as authentic protoxin, was observed tobe produced by transformed E. coli cells containing pBR322 derivativeshaving such large DNA segments containing the HD-1-Dipel gene orsubclones of that gene. This indicated that the Bacillus gene wastranscribed, probably from its own promoter, and translated in E. coli.Additionally, this finding suggested that the toxic activity of theprotein product is independent of the location of its synthesis. Thatthe gene was expressed when the fragment containing it was inserted intothe vector in either orientation suggests that transcription wascontrolled by its own promoter. Whiteley et al., supra, reported aconstruction deleting the 3′-end of the HD-1 toxin coding sequencesalong with the nontoxin coding sequence of the protoxin. Thetranscriptional and translational start sites, as well as the deducedsequence for the amino-terminal 333 amino acids of the HD-1-Dipelprotoxin, have been determined by nucleic acid sequencing (H. C. Wong etal. (1983) J. Biol. Chem. 258:1960-1967). The insecticidal gene wasfound to have the expected bacterial ribosome binding and translationalstart (ATG) sites along with commonly found sequences at −10 and −35(relative to the 5′-end of the mRNA) that are involved in initiation oftranscription in bacteria such as B. subtilis. Wong et al., supralocalized the HD-1 crystal protein gene by transposon mutagenesis, notedthat transposon insertion in the 3′-end of the gene could result inproduction in E. coli of 68kD peptides, but did not report anyinsecticidal activity to be associated with extracts of strains thatproduce 68kD peptides while lacking 130 kD protoxin.

A. Klier et al. (1982) EMBO J. 1:791-799, have reported the cloning ofthe crystal protein-gene from B. thuringiensis strain berliner 1715 inpBR322. Using the enzyme BamHI, a large 14 kbp fragment carrying thecrystal protein gene was moved into the vector pHV33, which canreplicate in both E. coli and Bacillus. In both E. coli and sporulatingB. subtilis, the pHV33-based clone directed the synthesis of full-size(130 kD) protoxin which formed cytoplasmic inclusion bodies and reactedwith antibodies prepared against authentic protein. Extracts of E. colicells harboring the pBR322 or pHV33-based plasmids were toxic to larvae.In further work, A. Klier et al. (1983) Nucleic Acids Res. 11:3973-3987,have transcribed the berliner crystal protein gene in vitro and havereported on the sequence of the promoter region, together with the first11 codons of the crystal protein. The bacterial ribosome binding andtranslational start sites were identified. Though the expected “−10”sequence was identified, no homology to other promoters has yet beenseen near −35.

G. A. Held et al. (1982) Proc. Natl. Acad. Sci. USA 77:6065-6069reported the cloning of a crystal protein gene from the variety kurstakiin a phage X-based cloning vector Charon4A. E. coli cells infected withone of the Charon clones produced antigen that was the same size as theprotoxin (130 kD) and was toxic to larvae. A 4.6 kbp EcoRI fragment ofthis Charon clone was moved into pHV33- and an E. coli plasmid vector,pBR328. Again, 130 kD antigenically identifiable crystal protein wasproduced by both E. coli and B. subtilis strains harboring theappropriate plasmids. A B. thuringiensis chromosomal sequence whichcross-hybridized with the cloned crystal protein gene was identified inB. thuringiensis strains which do not produce crystal protein duringsporulation.

SUMMARY

In pursuance of goals detailed below, the present invention provides DNAplasmids carrying partial protoxin genes, a partial protoxin being apolypeptide comprising part of the amino acid sequence ofnaturally-occurring toxin and often other amino acid sequences butlacking some of the naturally-occurring protoxin amino acid sequences.These genes are expressible in E. coli and Bacillus. Unexpectedly, thepartial protoxins produced by these genes as disclosed herein haveproven to be toxic to insect larvae. Methods useful toward constructionof partial protoxin genes and expression of partial protoxin proteinsare also provided. The partial protoxin proteins have properties thatare advantageous in use, over naturally-occurring crystal protein.

The Bacillus thuringiensis crystal protein is useful as an insecticidebecause it is highly specific in its toxicity, being totally nontoxicagainst most nontarget organisms. As the crystal protein is crystallineand therefore is of a particulate nature, and as it is a protoxin, thecrystal protein is not water-soluble or active unless previouslysubjected to chemical and enzymatic treatments that solubilize andactiviate it. As protoxin crystals must be ingested for toxicity, thecrystal must be located where they will be eaten by larvae, while adiffusable activated toxin can have toxic effects over a more diffuseregion. Also, one need not take precautions against the settling out ofsolution of soluble crystal protein derivatives. It is an object of thepresent invention to provide directly a water-soluble crystal proteinderivative or toxin thereby bypassing inconvenient prior art methods ofsolubilization and activation. Biological synthesis of partial protoxingene products is also advantageous over synthesis of complete protoxin,as synthesis of the partial protoxin, having a lower molecular weightthan a complete protoxin, constitutes a lesser drain on the metabolicresources of the synthesizing cell. Also, transformation and expressionof partial protoxin genes avoids the formation of crystallineprotoxin-containing inclusion bodies within cells, e.g. plant cells,that may disrupt cellular function or prove otherwise deleterious to anorganism producing a crystalline insecticidal protein.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 presents both restriction endonuclease maps and the sequencingstrategy employed to sequence the B. thuringiensis var. kurstaki HD-73crystal protein gene. The dots indicate the position of the 5′-endlabeling and the arrows indicate the direction and extent of sequencingpBt73-16 contains a fusion of crystal protein coding sequences frompBt73-10 and pBt73-161;

FIG. 2 diagrams the construction of plasmids containing complete orpartial B. thuringiensis var. kurstaki HD-73 protoxin genes. A: Ligationof pBt73-10, having the 5′-end of the protoxin gene, to a pBt73-161HindIII fragment containing the 3′-end of the gene to constructpBt73-1.6; B: Aval fragment removal from pBt73-3 to generate a partialprotoxin gene; C: pBt73-498 isolated from a B. thuringiensis var.kurstaki HD-73 PstI library containing a partial protoxin gene.

FIG. 3 discloses the complete nucleotide sequence of the B.thuringiensis var. kurstaki HD-73 protoxin gene. The derived amino acidsequence is given below.

FIG. 4 compares the complete HD-73 protoxin gene sequence disclosedherein (FIG. 3) with a published partial sequence of the HD-1-Dipelcrystal protein gene (H. C. Wong et al. (1983) J. Biol. Chem.258:1960-1967). Differences between the sequences are indicated by thebase and amino acid changes, the type sequence being that disclosedherein. The numbering corresponds to that of FIG. 3.

DETAILED DESCRIPTION OF THE INVENTION

The following definitions are provided in order to remove ambiguities tothe intent or scope of their usage in the specification and claims.

Complete protoxin, or protoxin, refers herein to a protein encoded by aB. thuringiensis crystal protein gene. In the variety kurstaki, thecomplete protoxin has an approximate molecular weight of 130,000Daltons.

Complete toxin, or toxin, refers herein to an insecticidal proteinderived from a crystal protein, in particular, that part of the protoxinthat is refractory towards processes, such as proteolytic digestion,that activiate protoxin in nature. In the variety kurstaki, the completeprotoxin has an approximate molecular weight of 68,000 Daltons and islacking the carboxy-terminal half of the protoxin.

Partial protoxin refers herein to a protein having part of the aminoacid sequence of protoxin and lacking part of the amino acid sequence ofthe carboxy-terminus of the protoxin but not the carboxy-terminus of thetoxin. Modifications of protoxin amino acid sequence, including adeletion at the amino-terminus of the toxin, may or may not be present.The partial protoxin may have at its carboxy-terminus an amino acidsequence not present in the complete protoxin. In other words, astructural gene open reading frame encoding partial protoxin may belacking sequences encoding the carboxy terminus of the protoxin but notsequences encoding the carboxy-terminus of the toxin, and may includesequences coding for additional amino acids not present in the completeprotoxin.

Complete protoxin gene, partial protoxin gene, and toxin gene referherein to structural genes encoding the indicated proteins, eachstructural gene having at its 5′-end a 540 . . . ATG . . .3′translational start signal and at its 3′-end a translational stop signal(TAG, TGA, or TAA). As is well understood in the art, the start and stopsignals must be in the same reading frame, i.e. in the same phase, whenthe mRNA encoding a protein is translated, as translational stop codonsthat are not in frame are ignored by the translational machinery and arefunctionally nonexistant. Modifications of the genetic structure, e.g.insertion of an intron that in a eukaryotic cell would be spliced out ofthe RNA transcript, are not excluded as long as the designated proteinis encoded by the transcript Underlying the present invention is asurprising discovery: that the carboxy-terminal half of the crystalprotein protoxin, encoded by the 3′-half of the protoxin gene, is notnecessary for toxicity, and that a variety of protoxin gene productsmissing the natural carboxy-terminus (i.e. partial protoxin geneproducts) are processed in vivo in E. coli to a polypeptide essentiallyindistinguishable from in vivo or in vitro proteolytically-derivedtoxin. This last aspect constrains the sequence of the partial protoxingene; partial protoxin gene sequences 3′ from the codon encoding thecarboxy-terminus of the complete toxin are removed.

Production of an insecticidal protein by means of expression of apartial protoxin gene combines specific teachings of the presentdisclosure with a variety of techniques and expedients known in the art.In most instances, alternative expedients exist for each stage of theoverall process. The choice of expedients depends on variables such asthe choice of B. thuringiensis strain and protoxin gene startingmaterials, means for and particulars of premature translationaltermination, vector carrying the artificial partial protoxin gene,promoters to drive partial protoxin gene expression, and organisms intowhich the partial protoxin gene/promoter combination is transformed andexpressed. Many variants are possible for intermediates and intermediatesteps, such as organism vector and DNA manipulation strategy.

In the practice of this invention one will ordinarily first obtain arecombinant DNA molecule carrying a complete protoxin gene or a fragmentof a protoxin gene. The means for constructing such recombinant DNAmolecules are well known in the art. If the desired protoxin is carriedby a Bacillus plasmid, one may prepare DNA enriched for the gene byfirst isolating that plasmid, as has been exemplified herein.Alternatively, one may make a collection of recombinant DNA-containingstrains from total B. thuringiensis DNA that is statistically likely tohave at least one representative of a protoxin gene (i.e. a genomicclone library). The Bacillus DNA may be digested to completion with arestriction endonuclease that cleaves DNA rarely (a six-base-cutter likeHindIII or PstI averages one site in about 4 kbp) or may be digestedincompletely (i.e. partial digestion) with an enzyme that cleaves often(a four-base-cutter like Sau3AI averages one site in about 0.25 kbp),adjusting digestion conditions so the cloned DNA fragments are largeenough to be likely to contain a complete protoxin gene. The BacillusDNA is then ligated into a vector. Commonly the vector is one that canbe maintained in E. coli, though vectors maintainable in Bacillusspecies are also useful. The Bacillus DNA/vector combinations are thentransformed into appropriate host cells. After a collection ofcandidates are created, a strain containing a protoxin gene/vectorcombination may be identified using any of a number expedients known tothe art. One can grow candidates on nitro-cellulose membrane filters,lyse the cells, fix the released DNA to the filters, and identifycolonies containing protoxin DNA by hybridization. The hybridizationprobe can be derived from sources including a different clonedcross-hybridizing protoxin gene, sporulation-stage specific B.thuringiensis RNA, or a synthetic nucleic acid having a protoxinsequence deduced from the protoxin amino acid sequence. If the protoxingene is expressed in its host, screening using bioassays forinsecticidal activity or using immunological methods is possible.Immunological methods include various immunoassays (e.g.radioimmunoassays and enzyme-linked immunoassays) and a method analogousto the probing of nitrocellulose-bound DNA. Colonies grown onnitrocellulose filters are lysed, protein is bound to the filters, andcolonies containing protoxin protein are identified using enzyme- orradioisotope-labeled antibodies.

The construction of recombinant DNA molecules containing completeprotoxin genes, partial protoxin genes, and incomplete toxin genes canbecome inextricably tied to each other. Indeed, in the experimental workdescribed herein, the original intention was to isolate a completeprotoxin gene before creating and biologically testing variants deletedin their 3′-sequences. Though published studies suggested an HD-73protoxin gene to be located completely on an approximately 6.7 kbpHindlIl (H. R. Whitely et al. (1982) in Molecular Cloning and GeneRegulation in Bacilli, eds. A. T. Ganesan et al., pp. 131-144), theHD-73 gene isolated herein was discovered to be interrupted by a HindIIIsite resulting in loss of the 3′-end of the protoxin gene during HindIIIdigestion, e.g. as in pBt73-10 and pBt73-3. An extreme case of31-deletion is when sequences encoding the carboxy-terminus of the toxinare missing from the initially cloned gene fragment, resulting in lackof insecticidal activity in the expressed polypeptide, e.g. as inpBt73-498. Similar events can lead to isolation of gene fragmentslacking 5′-sequences, e.g. as in pBt73-161. Conversely, should oneintend to construct a partial protoxin gene, initially a completeprotoxin gene may fortuitously be isolated. The isolation of missinggene fragments and their use in reconstruction of larger partial genesand complete genes is well understood in the art of recombinant DNAmanipulations and is exemplified herein. Generally, one uses the genefragment one already has to make a probe that is then used to look forflanking sequences that overlap with the probe. Libraries made usingpartial restriction enzyme digestion conditions can be screened directlyfor Bacillus DNA fragments overlapping with the probe. Libraries madeusing complete restriction enzyme digestion must have been made using adifferent enzyme than was used to make the probe-supplying plasmids. Asis understood in the art, it is advantageous to map flanking restrictionsites by means of Southern blots before constructing a second library.It is also advantageous to sequence or otherwise characterize theoverlaps so as to be sure the two fragments are derived from the samegene, and to sequence the suture between the two fragments so as to besure that the fusion has been accomplished as planned and that the openreading frame has been preserved, e.g. that no frameshift mutations havebeen introduced.

A partial protoxin gene is a protoxin generating naturally-occurringcoding sequence removed from its 3′-end. By definition, a codingsequence is terminated at its 3′-end by a translational stop signal.Removal of a 3′-end sequence entails translational termination at a newsite and, as the stop signal is approached, may entail departure fromthe naturally-encoded protoxin amino acid sequence. Coding sequences canbe removed in several ways. The native stop signal need not bephysically deleted; it need only be made inaccessable to ribosomestranslating a protoxin-encoding mRNA transcript. One means for makingthe native stop inaccessible is by introduction of a frameshiftmutation, usually an insertion or deletion of one or two base pairs,5′-to the native translational stop site, thereby shifting the nativestop out of the reading frame of the toxin and shifting another TAA,TAG, or TGA sequence into the toxin's reading frame. Another means formaking the native stop site inaccessible is by substitution of one tothree base pairs, or insertion of a stop signal, 5′-to the native stop,thereby directly creating a stop codon at that site. As is wellunderstood in the art, substitutions and frameshift mutations can beintroduced by a number of methods, including oligonucleotide-directed,site-specific mutagenesis. Frameshift mutations may also be created bycleaving DNA with a sticky-end-generating restriction enzyme followed byconverting the sticky-ends to blunt-ends and religation. A number ofembodiments involve deleting nontoxin protoxin sequences from the3′-half of the protoxin gene. If the deletion is flanked on either sideby protoxin gene sequences, the deletion may introduce a frameshiftleading to utilization of a new stop codon. If the deletion preservesthe reading frames, it will lead to utilization of the naturally usedstop codon while deleting part of the nontoxin protoxin gene sequence.Should the deletion remove the 3′-end of the protoxin structural gene,the open reading frame defined by the toxin will run into nonprotoxinDNA sequences and will eventually terminate in a stop codon in thatreading frames (i.e. a stop codon in frame). Nonprotoxin Bacillus DNA,vector DNA, synthetic oligonucleotides, and DNA naturally functional ina eukaryotic cell additionally having a polyadenylation site (i.e. asite determining in a eukaryotic cell the 3′-end of a transcript) 3′-tothe stop codon, are all examples of nonprotoxin DNAs that may encode apartial protoxin stop codon.

As one of the goals of this invention is to express the partial protoxingene in a living cell, the artificially constructed partial protoxingene must be under control of a promoter capable of directingtranscription in the desired cell type, a consideration well understoodin the art. Generally, one uses the recombinant DNA techniques to placethe structural gene and a promoter, the latter being known to drivetranscription in the cell in which expression is desired, in suchposition and orientation with respect to one another that the structuralgene is expressed after introduction into recipient cell. A special caseis when during the isolation of the protoxin structural gene, a protoxingene promoter is-isolated along with the protoxin structural gene, theprotoxin promoter being the promoter which in B. thuringiensis drivesthe expression of the protoxin gene. As part of the present invention,the promoter/protoxin gene combination, which may also be referred to asa Bacillus-expressible complete protoxin- gene, was found to driveexpression in E. coli of complete and partial protoxin genes. InBacillus this HD-7.3 promoter drives protoxin gene transcription onlyduring sporulation.

The promoter/partial protoxin structural gene combination is then placedin a known vector suitable for maintenance in the desired cell type. Thepromoter/structural gene/vector combination is then transformed by anappropriate technique known in the art into a cell of that cell type orfrom which that cell type may be derived, and partial protoxinexpression may be detected as described above. M. J. Adang and J. D.

Kemp, and R. F. Barker and J. D. Kemp, respectively U.S. Pat. appl. Ser.Nos. 535,354 and 553,786, exemplify expression of the pBt73-10 partialprotoxin gene in plant cells under control of T-DNA promoters. Thepresent application exemplifies expression of several partial protoxingene constructs in E. coli cells and minicells under control of apromoter derived from the same Bacillus-expressible complete protoxingene. Expression of partial protoxin genes under control of natural orsynthetic E. coli promoters will-be well understood by those of ordinaryskill in the art, as will be expression in sporulating cells of thegenus Bacillus under control of a protoxin-derived Bacillus promoter,,and expression in other organisms under control of appropriatepromoters.

EXAMPLES

The following Examples utilize many techniques well known and accessibleto those skilled in the arts of molecular biology; such methods arefully described in one or more of the cited references if not describedin detail herein. Enzymes are obtained from commercial sources and areused according to the vendor's recommendations or other variations knownto the art. Reagents, buffers and culture conditions are also known tothose in the art. Reference works containing such standard techniquesinclude the following: R. Wu, ed. (1979) Meth. Enzymol. 68, R. Wu etal., eds. (1983) Meth. Enzymol. 100 and 101, L. Grossman and K. Moldave,eds. (1980) Meth. Enzymol. 65, J. H. Miller (1972) Experiments inMolecular Genetics, R. Davis et al. (1980) Advanced Bacterial Genetics,R. F. Schleif and P. C. Wensink (1982) Practical Methods in MolecularBiology, and T. Maniatis et al. (1982) Molecular Cloning, and R. L.Rodriguez and R. C. Tait (1983), Recombinant DNA Techniques.Additionally, R. F. Lathe et al. (1983) Genet. Engin. 4:1-56, makeuseful comments on DNA manipulations.

Textual use of the name of a restriction endonuclease in isolation, e.g.“BclI”, refers to use of that enzyme in an enzymatic digestion, exceptin a diagram where it can refer to the site of a sequence susceptible toaction of that enzyme, e.g. a restriction site. In the text, restrictionsites are indicated by the additional use of the word “site”, e.g. “BclIsite”. The additional use of the word “fragment”, e.g. “BclI fragment”,indicates a linear double-stranded D14A molecule having ends generatedby action of the named enzyme (e.g. a restriction fragment). A phrasesuch as “BclI/Smal fragment” indicates that the restriction fragment wasgenerated by the action of two different enzymes, here BclI and SmaI,the two ends resulting from the action of different enzymes. Note thatthe ends will have the characteristics of being “blunt” (fullybase-paired) or “sticky” (i.e. having an unpaired single-strandedprotuberance capable of base-pairing with a complementarysingle-stranded oligonucleotide) and that the sequence of a sticky-endwill be determined by the specificity of the enzyme which produces it.

Plasmids, and only plasmids, are prefaced with a “p”, e.g., pBR322 orpBt73-10, and strains parenthetically indicate a plasmid harboredwithin, e.g., E. coli HClCl (pBt73-10). Deposited strains are listed inExample 6.3.

Example 1 Molecular Cloning

1.1: PBt73-10 and pBt73-3

The crystal protein gene in Bacillus thuringiensis var. kurstaki HD-73is located on a 50 megadalton (MD) plasmid. At least part of the gene iscontained in a 6.7 kbp HindIII fragment (J. W. Kronstad et al. (1983) J.Bacteriol. 154:419-428). The 50 MD plasmid was enriched from HD-73 usingsucrose gradient centrifugation. A HD-73 library was constructed byfirst digesting this plasmid DNA with HindIII. The resulting fragmentswere mixed with and ligated to HindlIl-linearized pBR322 (F. Bolivar etal. (1978) Gene 2:95-113) and transformed into E. coli HB101.Ampicillin-resistant tetracycline-sensitive transformants were screenedby digesting isolated plasmidDNA with HindIII and choosing those cloneswith 6.7 kilobase pair (kbp) inserts. Colonies containing plasmidspBt73-3 and pBt73-10 were selected from the HD-73 library for furtheranalysis using an insect bioassay. These clones were grown in L-brothand a 250 fold concentrated cell suspension was sonicated and theextract applied to the surface of insect diet. Neonatal Manduca sexta(tobacco hornworm) larvae were placed on the diet for one week. Insectlarvae fed extracts of strains harboring pBt73-3 or pBt73-10 did notgrow and all larvae died in 2 to 5 days. There was no apparentdifference between the larvae fed these extracts and those fedinsecticidal protein purified from cells of B. thuringiensis.

Restriction enzyme analysis (FIG. 1) of pBt73-3 and pBt73-10 showed thatthe two plasmids had identical 6.7 kbp B. thuringiensis DNA fragmentsinserted into the pBR322 vector in opposite orientations (FIG. 2). Notethat pBt73-3 can be converted to pBt73-10 by digestion with HindIII,religation, and transformation into HB101 followed by appropriateselection and screening steps. The two plasmids are functionallyequivalent for all manipulations described herein.

pBt73-10 was used to further probe the transformants from the HD-73plasmid library. Sixteen of the 572 colonies hybridized to the insert ofclone pBt73-10 and all had the characteristic 6.7 kbp HindIII fragment.Further restriction enzyme analysis showed these clones to all be one ofthe two possible orientations in pBR322 of the same DNA fragment. Thissuggested there could be a single crystal protein gene in strain HD-73.That these clones represent the only insecticidal protein gene in HD-73was confirmed by hybridizing labeled pBt73-10 probe to Southern blots ofHD-73 plasmid DNA digested with HindIII, BglII or Sall. None of theseenzymes has a restriction site in our cloned crystal protein gene.Hybridization results showed a single band of B. thuringiensis cellularDNA hybridized with pBt73-10 and further indicated that HD-73 has asingle insecticidal crystal protein gene. A number of other clones wereidentified by hybridization with a probe made from pBt73-10. Restrictionmapping showed that these clones are all identical to either pBt73-3 orpBt73-10, further supporting the conclusion that the HD-73 has a singlecrystal protein gene.

1.2: pBt73-161 and pBt73-498

Immunodetection of electrophoretically separated peptides on proteinblots and DNA sequencing showed that pBt73-10 and pBt73-3 each containeda partial protoxin gene. To reconstruct a complete protoxin gene,flanking DNA restriction sites were identified by Southern blots ofrestriction digests, a well-known technique, and overlapping clones wereselected from a PstI library made from 50 MD plasmid-enriched DNA asfollows. 50 MD plasmid DNA, enriched by sucrose gradient centrifugationas above, was digested to completion with PstI, mixed with and ligatedto PstI-linearized pBR322, and transformed into HB101.Tetracycline-resistant transformants were screened essentially asdescribed by W. D. Benton and R. W. Davis (1977) Science 196:180-182,using a probe nick-translated from the 6.7 kbp HindIII insert ofpBt73-10. Plasmid DNAs isolated from strains which bound the probe werecharacterized by restriction enzyme analysis. Two strains choosen forfurther work harbored pBt73-498 (FIG. 2C), which contains the 5′-end ofa crystal protein gene and pBt73-161 (FIGS. 1 and 2A) which contains the3′-end of a crystal protein gene.

1.3: pBt73-16

The 5′- and 3′-ends of the protoxin gene were fused together at theunique HindlIl site to form a complete protoxin gene (FIG. 2). pBt73-10DNA was digested with BamHI, ligated to itself, and transformed intoHB101. Plasmid DNAs from ampicillin-resistant transformants werecharacterized by restriction enzyme analysis and a strain was identifiedthat harbored a plasmid, designated pBt73-10(Bam), having single BamHIand HindIII sites due to deletion of a small HindIII site-bearing BamHIfragment. A 5 kbp HindlIl fragment of pBt73-161, isolated by agarose gelelectrophoresis, was mixed with and ligated to HindIII-digesteddephosphorylated (by bacterial alkaline phosphatase) pBt73-10(Bam) DNA.After the ligation mixture was transformed into HB101, plasmid DNAisolated from ampicillin-resistant tetracycline-sensitive transformantswas characterized by restriction enzyme analysis. A transformant wasidentified that harbored a plasmid, designated pBt73-16, carrying acomplete protoxin gene (FIG. 1).

1.4: pBt73-3(Ava)

Convenient AvaI restriction sites in clone pBt73-3 were used to remove a3′ segment of the protoxin gene. pBt73-3 DNA was digested with AvaI,ligated to itself, and transformed into HB101. Plasmid DNAs isolatedfrom ampicillin-resistant transformants were characterized byrestriction enzyme analysis and a colony harboring a plasmid, designatedpBt73-3(Ava), was identified (FIG. 2A).

1.5: pBt73-Sau3AI

50 MD HD-73 plasmid DNA was partially digested with Sau3AI, arestriction enzyme that produces 5′GATC . . .3′ sticky-ends compatiblefor ligation with sticky-ends produced by the enzymes BamHI, BclI, andBglII. The HD-73 DNA fragments were mixed with and ligated todephosphorylated BamHI-linearized pBR322, and the ligation mixture wastransformed into HB101. Ampicillin-resistant transformants were screenedas described in Example 1.2 by the method of Benton and Davis, supra,using the 6.7 kbp HindIII pBt73-10 probe, and a colony was identifiedthat harbored a plasmid designated herein as pBt73-Sau3AI. The insert ofpBt73-Sau3AI was about 3 kbp long, carried a partial protoxin genehaving removed from its 3′-end Bacillus DNA 3′ from the first Sau3Al3′-from the AvaI site used to construct pBt73-3(Ava).

Example 2 Nucleotide sequence of the crystal protein gene

The complete nucleotide sequence of the protoxin gene from B.thuringiensis var. kurstaki HD-73 is shown in FIG. 3, beginning with anATG initiation codon at position 388 and ending with a TAG terminationcondon at position 3.924. The total length of the B. thuringiensis HD-73gene was 3,537 nucleotides, coding for 1,178 amine acids producing aprotein with a molecular weight of 133,344 Daltons (D). The 5′-end ofthe coding sequence was confirmed experimentally using a coupledDNA-direct in vitro system to form the amino-terminal dipeptide.

The base composition of the protoxin gene, direct repeats, invertedrepeats, restriction site locations, and the codon usage are inherent inthe disclosed sequence (FIG. 3). There was no bias towards prokaryoticor eukaryotic condon preferences.

Example 3 Expression of completed and partial protoxin genes in E. coli

3.1: pSt73-16

Shown in Table 2 are the E. coli clones which contain complete orpartial protoxin genes. Protein blots of these E. coli extracts wereused to detect immunologically crystal protein antigen production bythese clones (FIG. 3). Plasmid pBt73-16 was shown by DNA sequencing tocontain a complete protoxin gene and E. coli cells containing thisplasmid synthesized a peptide of approximately 130 kD that comigratedduring SDS polyacrylamide gel electrophoresis with solubilized protoxinprotein and cross-reacted strongly with antiserum to crystal protein. Aseries of indiscrete peptide bands were observed between this majorpeptide of 68 kD. High pressure liquid chromatographic analysisindicated that the 68 kD peptide was similar if not identical to theprotease-resistant portion of the protoxin. A mini-cell strain was usedto analyze the peptide products of pBt73-16. The results were similar tothose of the immunoblots indicating a lack of stability of the crystalprotein in E. coli that results in degradation of the 130 kD peptide to68 kD.

3.2: pSt37-10 and pBt73-3

pBt73-10 contains the 5′2,825 bp of the HD-73 protoxin gene encoding apartial protoxin peptide sequence of 106,340 D. Translation shouldcontinue into pBR322 encoded sequence for an additional 78 bases,thereby resulting in synthesis of a peptide having a total molecularweight of approximately 106,560 D.

Analyses on the protein produced by the E. coli clones showed thatpBt73-3 and pBt73-10 encoded soluble antigens that formed a precipitinband with antiserum to B. thuringiensis insecticidal protein inOuchterlony diffusion slides. Cell extracts were analyzed on 10% SDSpolyacrylamide gels, transferred to nitrocellulose, and immunologicalreactions done with antibody and [¹²⁵I]-protein A. No band was found at130 kD where denatured protoxin is observed, however, a peptide of about68 kD was seen that binds crystal protein antibody, and was identical insize to activated toxin. A 104 kD peptide was also observed. Thesepeptides accounted for approximately 0.1% of the total E. coli protein.High pressure liquid chromatographic analysis indicated that the 68 kDpeptide was similar if not identical to the protease-resistant protionof the protoxin. In E. coli mini-cells harboring pBt73-10 expressedpeptides of approximately 104 kD and 68 kD. These data showed that the104 kD peptide was not stable in E. coli but it was degraded to arelatively stable form of 68 kD.

3.3: pBt73-3(Ava) and pBt73-Sau3AI

E. coli containing pBt73-3(Ava)-as constructed encodes an amino-terminal68,591 D peptide of the protoxin gene along with 32 amino acids encodedby pBR322 for an expected translation product of about 72 kD. E. coliextracts containing pBt73-3(Ava) on immunoblots produced a peptide ofapproximately 68 kD. High pressure liquid chromatographic analysisindicated that the 68 kD peptide was similar if not identical to theprotease-resistant portion of the protoxin. E. coli mini-cells harboringpBt73-3(Ava) also produced a 68 kD peptide.

Extracts of pBt73-Sau3AI-containing HB11 and mini-cells gave similarresults to pBt73-3(Ava) when investigated with immunoblots.

3.4: pBt73-498

A truncated toxin gene is carried by pBt73-498. This plasmid has anN-terminal protoxin peptide of 53,981 D fused to a pBR322 peptide of2,700 D for an expected peptide totaling approximately 57 kD. In E. coliextracts on immunoblots there was a peptide of 45 kD that weaklycross-reacted with antiserum to crystal protein, whereas in the E. colimini-cell, strain pBt73-498 produced a slightly larger peptide ofapproximately 50 kD. As it is difficult to compare the exact peptidesizes by SDS polyacrylamide gel electrophoresis, the difference in theapparent molecular weights for pBt73-498 peptides may not besignificant.

3.5: Common features

That the exact means for translational termination in the pBR322-encodedpartial protoxin peptides was not important was demonstrated by thefinding that insecticidal activity was encoded by B. thuringiensis DNAinserts (pBt73-3 and pBt73-10) having either orientation within thepBR322 vector, and also by pBt73-3(Ava) and pBt73-Sau3A. Presumably theinitially translated protoxin amino acid residues carboxy-terminal tothe ultimate carboxy-terminus of the toxin were removed in E. coli by aproteolytic process similar to that which naturally activates thecrystal protein.

Experiments utilizing a coupled DNA-direct in vitro system (H. Weissbachet al. (1984) Biotechniques 2:16-22) determine the amino-terminaldipeptides produced by pBt73-16, pBt73-3, pBt73-10, pBt73-3(Ava), andpBt73-498 indicated that all of these structural genes had the sametranslational start site, encoding fMet-Asp.

The 68 kD peptides were not distinguished from each other or activatedcrystal protein toxin by any tests used by the time this application wasfiled.

Example 4 Properties of the expressed gene products

4.1: Insect bioassays of the E. coli clones

Table 4 lists the relative toxicities of E. coli containing complete ortruncated protoxin genes. As expected, pBt73-16 containing the completegene encodes the product that was the most toxic to Manduca sextalarvae. However, pBt73-10, pBt73-Sau3AI (having toxicity about the sameas p~t73-3(Ava)), and pBt73-3(Ava) which expressed the N-terminal 68 kDpeptide in E. coli were unexpectedly both lethal to the larvae. Thisindicates the N-terminal 68 kD peptide is sufficient for biologicalactivity. Extracts of E. coli cells harboring pBt73-498 were tested athigh concentrations. Growth of the larvae was not generally inhibitedand extracts were not found to be lethal during the six day course ofthe bioassay. Bioassay of fractions collected high pressure liquidchromatographic separations of extracts of HD11 strains containingpartial protoxin genes showed that the 68 kD peptide was toxic to insectlarvae.

4.2: Solution properties of peptides

E. coli extracts were fractionated by centrifugation and the resultantfractions were assayed immunologically for crystal protein and itsderivatives after SDS-polyacrylamide gel electrophoresis and blottingonto a solid support. Solubility of a particular-sized peptide did notvary with the specific plasmid from which it was derived. The 130 kDprotoxin was totally sedimented by a 16,000 x g, 5 min spin, indicatingthat it was insoluble as would be expected for a crystalline protein.The 68 kD toxin was observed in both the pellet and supernatants of botha 16,000 x g, 5 min spin and a 100,000 x g, 5 min spin. This indicatedthat it could be highly soluble though it might interact with itself orother E. coli extract components, probably because of the extremelyhydrophobic nature of its amino acid composition. The 104 kD partialprotoxin encoded by pBt73-10 was observed to be totally soluble afterboth 16,000 x g and 100,000 x g spins, indicating that the solubilityproperties of the toxic moiety can be manipulated by changing thecarboxy-terminal peptide moiety.

Example 5 Discussion and comparison with publications

The protoxin gene from B. thuringiensis var. kurstaki HD-73 was clonedand the complete nucleotide sequence of the gene was determined and isdisclosed herein. The primary structure consisted of 3,537 nucleotidescoding for 1,178 amino acids encoding a protein having a molecularweight of 133,344 Daltons. The crystal protein of B. thuringiensis var.kurstaki HD-1-Dipel is reported to contain 1,176 amino acids (approx.mol. wt. 130 kD) (S. Chang (1983) Trends Biotechnol. 1:100-101). Thepublished sequence (H. C. Wong et al. (1983) J. Biol. Chem.258:1960-1967) available for comparison accounts for less than one-thirdof the protoxin gene. When the present sequencing data was compared withthe partial sequence of the 5′-end of the crystal protein gene from B.thuringiensis var. kurstaki HD-1-Dipel, 41 differences were found (FIG.3). All the changes occurred within the gene; only one occurred withinthe first 600 base paris (bp) at position 831 and the remaining 40occurred within the last 400 bp of the sequence available forcomparison. Twelve of these base changes resulted in amino aciddifferences. The promoter regions and the 5′-ends of the crystal proteingenes were very homologous. The majority of the changes occurred in thelast 400 bp of the compared partial sequence. The restriction maps ofgenes from B. thuringensis var. Kurstaki HD-1 (G. A. Held et al., (1982)Proc. Natl. Acad. Sci. USA 77:6065-6069), B. thuringiensis var. berliner1715 (A. Klier et al. (1982) EMBO J. 1:791-799), B. thuringiensis var.kurstaki HD-1-Dipel (H. E. Schnepf and H. R. Whitely (1981) Proc. Natl.Acad. Sci. USA 78:2893-2897), and the map of B. thuringiasis var.kurstaki HD-73 described in the present application all differextensively, indicating portions of the crystal protein gene can varyand yet the protein remains biologically active. The promoter region and5′-and sequences of the crystal protein genes of HD-1 and HD-73 strainsdiffer completely from the analogous sequences proposed for thechromosomal crystal proteingene of B. thuringiensis strain berliner 1715(A. Klier et al., (1983) Nutl. Acids Res. 11:3973-3987).

Previous S1 nuclease mapping on strain HD-1 has located two possibleinitiation of transcription start sites and also putative prokaryoticpromoter sequences at the −10 positions, but not homology was found tothe consensus sequence at the −35 position (Wong et al., supra). Theyalso indicate a prokaryotic ribosome bind site (J. Shine and L. Dalgarno(1974) Proc. Natl. Acad. Sci. USA 71:1342-1346) −3 bases from the ATSinitiation condon. Sequences of the promoter regions and the 5′-ands ofthe crystal protein genes are identical in both HD-1 and HD-73 strainsbut different than found in berliner (Klier et al. (1983) supra). It ishighly probable, due to the highly conserved nature of these regions,that the transcriptional start sites occurs in HD-73 at a similarposition of HD-1-Dipel.

In addition to E. coli containing a complete crystal protein gene, threeplasmids were constructed having various amounts of the 3′-codingsequence deleted. A coupled DNA-directed in vitro system was used asdescribed by H. Weissbach et al. (1984) Biotechniques 2:16-22, todetermine the amino-terminal dipeptides of these crystal proteinconstruction. In each plasmid the dipeptide synthesized was fMet-Asp,indicating that the translational start site of each crystal proteinconstruction is 5′. . . . AUGGAPu. . . .3′ (Met-Asp). These resultsagree with the start site observed for B. thuringiensis var. kurstakiHD-1-Diepl (Wong et al., supra). A. Klier et al. (1983) supra, reporteda completely different translational start site for B. thuringiensisvar. berliner 1715.

E. coli (pBt73-16), which harbors a plasmid bearing a complete crystalprotein gene, E. coli (pBt73-10), and E. coli (pBt73-3(Ava)) allproduced a peptide of approximately 68 kD. This corresponds in size tothe fragment of the protoxin others have reported to betrypsin-resistant (R. M. Faust et al. (1974) J. Invertebr. Pathol.24:365-373; T. Yamamoto and R. E. McLaughlin (1981) Biochem. Biophys.Res. Commun. 103:414-421; and H. E. Huber and P. Luthy (1981), inPathogenesis of Invertebrate Microbial Diseases, ed.: E. W. Davidson,pp. 209-234). Experiments using separation of peptides by high pressureliquid chromatography indicated that the 3′-truncated peptides producedby the E. coli strains described herein were indistinguishable from theprotease-resistant portion of the crystal protein. That extracts of E.coli (pBt73-10) or E. coli (pBt73-3(Ava)) were less toxic to insectsthan E. coli (pBt73-16) extracts of the complete gene was probably notdue to the loss of an active region of the toxin but rather to a lack ofstability in E. coli. E. coli (pBt73-498) produced a 45 kD peptide andwas not toxic to insects (Table 2).

Example 6 Experimental

6.61: Materials

Ultra pure urea was obtained from BRL (Gaithersburg, Md.),polyacrylamide from BDH (Poole, England), calf intestinal alkalinephosphatase from Boehringer (Mannheim, W. Germany), polynucleotidekinase from P. L. Biochemicals, Inc. (Milwaukee, Wis.), and [γ-³²p] ATPfrom New England Nuclear (Boston, Massachusetts). The restrictionenzymes AccI, Aval, BamhI, BglI, Clal, EcoRV, HincII, HpaI, KnI, RsaI,and XmnI were from New England Biolabs (Beverly, Mass.). EcoRi, HindlIl,PstI, XbaI, and XhoI from Promega Biotec (Madison, Wis.) and PvuII fromBRL (Gaithersburg, Md.). All enzymes were used in accordance tosupplier's specifications. Chemicals used for DNA sequencing reactionswere from vendors recommended by A. M. Maxam and W. Gilbert (1980) Meth.Enzymol. 65:499-560. X-omat AR5 X-ray film was supplied as rolls byEastman Kodak (Rochester, N.Y.). All other reagents were of analyticalgrade unless otherwise stated.

6.2: Sequencing reactions

All the sequencing reactions were done according to the methods wellknown in the art, of Maxam and Gilbert, supra, with modificationsdescribed by R. F. Barker et al. (1983) Plant Molec. Biol. 2:335-350,and R. F. Barker and J. D. Kemp, U.S. Pat. appl. ser. no. 553,786. Longsequencing gels (20 cm wide, 110 cm in length, and 0.2 mm thick) wereused to separate the oligonucleotides. The gel plates were treated withsilanes. Using these methods, 500 bp per end-labeled fragment wereroutinely sequenced.

The strategy used to sequence the crystal protein gene is shown in FIG.1. pBt73-10 was sequenced initially and found to contain an open readingframe of 2,825 bases from the start of the gene to the HindlIl site.pBt73-161 contained a 5.4 kb Psti fragment having the 3′ 711 bases ofthe pBt73-10 gene. The overlapping 1,037 bases of pBt73-10 and pBt73-161were identical. Those two individual plasmids were then fused at theHindIII site to form pBt73-16. Sequencing across that HindIII siteshowed that the open reading frame was maintained in pBt73-16. Computeranalysis of the sequence data was performed using computer programs madeavailable by Drs. 0. Smithies and F. Blattner (University of Wisconsin,Madison).

6.3: Bacterial strains

Bacillus thuringiensis var. kurstaki strain HD-73 (NRRL B-4488) was fromthe Bacillus Genetics Stock Collection. B. thuringiensis var. kurstakiHD-1 (NRRL B-3792) was isolated from Dipel (Abbott Laboratories).Eschericia coli strain HB11 (NRRL B-11371) (H. W. Boyer and D.Roulland-Dussoix (1969) J. Mol. Biol. 41:459-472 was used in alltransformations except in the mini cell experiments where E. coli 984was used (Example 3.7). E. coli HB101 (pBt73-10) is on deposit as NRRLB-15612 (this strain was designated E. coli HB101 (pl23158-10) whendeposited). E. coli HB101 (pBt73-16) is on deposit as NRRL B-15759.

6.4: Preparation of plasmids

Both pBR322 and B. thuringiensis plasmid DNA was prepared by an alkalinelysis method (H. C. Birnboim and J. Doly (1979) Nucl. Acids Res.7:1513-1523). Before cloning, B. thuringiensis plasmids werefractionated by centrifugation at 39,000 rpm in a Beckman SW40-1 rotorfor 90 min at 15° C. through 5%-25% sucrose gradients containing 0.55 MNaCl, 0.005 M NaEDTA, and 0.05M Tris-HCl, pH8.0 and the fractionsanalyzed on 0.5% agarose gels. Linearized vector DNAs were usuallydephosphorylated by incubation with bacterial alkaline phosphatasebefore being mixed with and ligated to a DNA intended for insertion intothe vector,

6.5: Preparation of antisera to crystal protein

B. thuringiensis strains HD-1-Dipel and HD-73 were grown to sporulationin modified G medium (A. I. Aronson et al. (1971) J. Bacteriol.106:1016-1025 and crystals were purified by three passes in Hypaque-76(Winthrop) gradients (K. Meenakshi and K. Jayaraman (1979) Arch.Microbiol. 120:9-14), washed with 1M NaCl, deionized water, andlyophilized. Crystals were solubilized in cracking buffer 1% SDS (sodiumdodecylsulfate), 2% 2-mercaptoethanol, 6 M urea, 0.01 M sodium phosphatepH 7.2 with 0.02% bromphenol blue by heating at 95° C. for 5 minutes.Electrophoresis was performed by a modification of the procedure of U.K. Laemmli (1970) Nature 227:680-685, as described previously (M. J.Adang and L. K. Miller (1982) J. Virol. 44:782-793). Gels were stainedfor 5 minutes, and destained 1 hour in deionized water. The 130 kD bandwas excised, lyophilized, and ground to a powder in a Wigl-BugAmalgamator (Crescent Manufacturing Company). Rabbits weresubcutaneously injected with 50 ng crystal protein, suspended incomplete Freund's adjuvant followed by two injections with 50 ng crystalprotein each in incomplete adjuvant over a four-week period. Monoclonalantibodies prepared against HD-73 crystal protein gave results identicalin interpretation to results obtained with polyclonal sera.

6.6: Immunodetection of blotted peptides

E. coli clones were grown overnight in L-broth, pelleted, and brought toa 100 times concentrated suspension with 10 mM NaCl, 10 mM Tris HCl pH8.0, and 1 mM EDTA containing phenylmethylsulfonyl fluoride (PMSF, aprotease inhibitor) to 200 ng/ml. The suspension was sonicated on iceand the extracts stored frozen. Electrophoresis of E. coli extracts wasas described above and immunodetection of peptides on blot Was accordingto the procedures of H. Towbin et al. (1979) Proc. Natl. Acad. Sci. USA76:4350-4354.

6.7: Preparation and labeling of E. coli mini-cells

Mini-cells were isolated as described by A. C. Frager and R. Curtiss III(1975) Curr. Top. Microbiol. Imnunol. 69:1-84, labelled with[³⁵S]methionine and processed for analysis by SDS-polyacrylamide gelelectrophoresis according to the procedures of S. Harayama et al. (1982)J. Bacteriol. 152:372-383.

6.8: Insect bioassays

Insects were obtained from commercial sources and kept essentially asdescribed by R. A. Bell and F. G. Joachim (1976) Ann. Entomol. Soc.Amer. 69:365-373, or R. T. Tamamoto (1969) J. Econ. Entomol.62:1427-1431. Bioassays for insecticidal protein were done by feedingextracts to larvae of Manduca sexta essentially as described by J. H.Schesser et al. (1977) Appl. Environ. Microbiol. 33:878-880. E. coliextracts for bioassays did not have PMSF in the sonication buffer.

TABLE I Insects susceptible to B. thuringiensis insecticidal protein

COLEOPTERA

Popillia japonica (Japanese beetle)

Sitophilus granarius (granary weevil)

DIPTERA

Aedes aegypti (yellow-fever mosquito)

A. atlanticus

A. cantans

A. capsius

A. cinereus

A. communis

A. detritus

A. dorsalis

A. dupreei

A. melanimon

A. nigromaculis (pasture mosquito)

A. punctor

A. sierrensis (western treehole mosquito)

A. sollicitans (brown salt marsh mosquito)

Aedes sp.

A. taeniorhynchus (black salt marsh mosquito)

A. tarsalis

A. tormentor

A. triseriatus

A. vexans (inland floodwater mosquito)

Anopheles crucians

A. freeborni

A. quadrimaculatus (common malaria mosquito)

A. sergentii

A. stephensi

Anopheles sp.

Chironomus plumosus ~ironomus: midges, biting)

Chironomus s.

C. tummi

Culex erraticus

C. inornata

C. nigripalus

C. peus

C. pipiens (northern house mosquito)

C. quinquefasciatus (C. pipiens fatigans) (southern house mosquito)

C. restuans

Culex sp.

C. tritaeniorhynchus

C. tarsalis (western encephalitis mosquito)

C. territans

C. univittatus

Culiseta incidens (Culiseta: mosquitos)

C. inornata

Diamessa s.

Dixa sp. (Dixa: midges)

Eusimulium (Simulium) latipes (Eusimulium: gnats)

Goeldichironomus holoprasinus

Haematobia irritans (horn fly)

Hippelates collusor

Odagmia ornata

Pales pavida

Polpomyia sp. (Polpomyia: midges, biting)

Polypedilum sp. (Polypedilum: midges)

Psorophora ciliata

P. columiae (confinnis) (Florida Glades mosquito, dark rice fieldmosquito)

P. ferox

Simulium alcocki (Simulium: black flies)

S. argus

S. cervicornutum

S. damnosum

S. jenningsi

S. piperi

S. tescorum

S. tuberosum

S. unicornutum

S. venustum

S. verecundum

S. vittatum

Uranotaenia inguiculata

U. lowii

Wyeomyia mitchellii (Wyeomyia: mosquitos)

W. vanduzeei

HYMENOPTERA

Athalia rosae (as colibri)

Nematus (Pteronidea) ribesii (imported currantworm)

Neodiprion banksianae (jack-pine sawfly)

Priophorus tristis

Pristiphora erichsonii (larch sawfly)

LEPIDOPTERA

Achaea janata (croton caterpillar)

Achroia grisella (lesser wax moth)

Achyra rantalis (garden webworm)

Acleris variana (black-headed budworm)

Acrobasis sp.

Acrolepia alliella

Acrolepiopsis (Acrolepia) assectella (leek moth)

Adoxophyes orana (apple leaf roller)

Aegeria (Sanninoidea) exitiosa (peach tree borer)

Aglais urticae

Agriopsis (Erannis) aurantiaria (Erannis: loopers)

A. (E.) leucophaearia

A. marginaria

Agrotis ipsilon (as ypsilon) (black cutworm)

A. segetum

Alabama argillacea (cotton leafworm)

Alsophila aescularia

A. pometaria (fall cankerworm)

Amorbia essigana

Anadeyidia (Plusia) peponis.

Anisota senatoria (orange-striped oakworm)

Anomis flava

A. (Cosmophila) sabulifera

Antheraea pernyi

Anticarsia gemmatalis (velvetbean caterpillar)

Apocheima (Biston) hispidaria

A. pilosaria (pedaria)

Aporia crataegi (black-veined whitemoth)

Archips argyrospilus (fruit-tree leaf roller)

A. cerasivoranus (ugly-nest caterpillar)

A. crataegana

A. podana

A. (Cacoecia) rosana

A. xylosteana

Arctia caja

Argyrotaenia mariana (gray-banded leaf roller)

A. velutinana (red-banded leaf roller)

Ascia (Pieris) monuste orseis

Ascotis selenaria

Atteva aurea (alianthus webworm)

Autographa californica (alfalfa looper)

A. (Plusia) gamma

A. nigrisigna

Autoplusia egena (bean leaf skeletonizer)

Azochis gripusalis

Bissetia steniella

Bombyx mori (silkworm)

Brachionycha sphinx

Bucculatrix thurberiella (cotton leaf perforator)

Bupolus piniarius (Bupolus: looper)

Cacoecimorpha pronubana

Cactoblastis cactorum (cactus moth)

Caloptilia (Gracillaria) invariabilis

C. (G) syringella (lilac leaf miner)

C. (G.) theivora

Canephora asiatica

Carposina niponensis

Ceramidia sp.

Cerapteryx graminis

Chilo auricilius

C. sacchariphagus indicus

C. suppressalis (rice stem borer, Asiatic rice borer)

Choristoneura fumiferana (spruce budworm)

C. murinana (fir-shoot roller)

Chrysodeixis (Plusia) chalcites (green garden looper)

Clepsis spectrana

Cnaphalocrocis medinalis

Coleotechnites (Recurvaria) milleri (lodgepole needle miner)

C. nanella

Colias eurytheme (alfalfa caterpillar)

C. lesbia

Colotois pennaria

Crambus bonifatellus (fawn-colored lawn moth, sod webworm)

C. sperryellus

Crambus spp.

Cryptoblabes gnidiella (Christmas berry webworm)

Cydia funebrana

C. (Grapholitha) molesta (oriental fruit moth)

C. (Laspeyresta) pomonella (codling moth)

Datana integerrima (walnut caterpillar)

D. ministra (yellow-necked caterpillar)

Dendrolimus pini

D. sibiricus

Depressaria marcella (a webworm)

Desmia funeralis (grape leaf folder)

Diachrysia (Plusia) orichalcea (a semilooper)

Diacrisia virginica (yellow woollybear)

Diaphania (Margaronia) indica

D. nitidalis (pickleworm)

Diaphora mendica

Diatraea grandiosella (southwestern corn borer)

D. saccharalis (sugarcane borer)

Dichomeris marginella (juniper webworm)

Drymonia ruficornis (s chaonia)

Drymonia sp.

Dryocampa rubicunda (greenstriped mapleworm)

Earias insulana

Ectropis (Boarmia) crepuscularia

Ennomos subsignarius (elm spanworm)

Ephestia (Cadra) cautella (almond moth)

E. elutella (tobacco moth)

E. (Anagasta) kuehniella (Mediterranean flour moth)

Epinotia tsugana (a skeletonizer)

Epiphyas postvittana

Erannis defoliaria (mottled umber moth)

E. tiliaria (linden looper)

Erinnysis ello

Eriogaster henkei

E. lanestris

Estigmene acrea (salt marsh caterpillar)

Eublemma amabilis

Euphydryas chalcedona

Eupoecilia ambiguella

Euproctis chrysorrhoea (Nygmi phaeorrhoea) (brown tail moth)

E. fraterna

E. pseudoconspersa

Eupterote fabia

Eutromula (Simaethis) pariana

Euxoa messoria (dark-sided cutworm)

Galleria mellonella (greater wax moth)

Gastropacha quercifolia

Halisdota argentata

H. caryae (hickory tussock moth)

Harrisina brillians (western grapeleaf skeletonizer)

Hedya nubiferana (fruit tree tortrix moth, green budworm)

Heliothis (Helicoverpa) armigera (Heliothis=Chloridea) (gram pod borer)

H. (H.) assulta

Heliothis peltigera

H. virescens (tobacco budworm)

H. viriplaca

H. zea (cotton bollworm, corn earworm, soybean podworm, tomatofruitworm, sorghum headworm, etc.)

Hellula undalis (cabbage webworm)

Herpetogramma phaeopteralis (tropical sod webworm)

Heterocampa guttivitta (saddled prominent)

H. manteo (variable oak leaf caterpillar)

Holcocera pulverea

Homoeosoma electellum (sunflower moth)

Homona magnanima

Hyloicus pinastri

Hypeuryntis coricopa

Hyphantria cunea (fall webworm)

Hypogymna morio

Itame (Thamnonoma) wauaria (a spanworm)

Junonia coenia (buckeye caterpillars)

Kakivoria flavofasciata

Keiferia (Gnorimoschema) lycopersicella (tomato pinworm)

Lacanobia (Polia) oleracea

Lamdina athasaria pellucidaria

L. fiscellaria fiscellaria (hemlock looper)

L. fisellaria lugubrosa (western hemlock looper)

L. fiscellaria somniaria (western oak looper)

Lampides boeticus (bean butterfly)

Leucoma (Stilpnotia) salicis (satin moth)

L. wiltshirei

Lobesia (=Polychrosis) botrana

Loxostege commixtalis (alfalfa webworm)

L. sticticalis (beet weuworm)

Lymantria (Porthetria) dispar (gypsy moth) (Lymantria: tussock moths)

L. monacha (nun-moth caterpillar)

Malacosoma americana (eastern tent caterpillar)

M. disstria (forest tent caterpillar)

M. fragilis (=fragile) (Great Basin tent caterpillar)

M. neustria (tent caterpillar, lackey moth)

M. neustria var. testacea

M. pluviale (western tent caterpillar)

Mamerstra brassicae (cabbage moth)

Manduca (Inotoparce) quinquemaculata (tomato hornworm)

M. (I.) sexta (tobacco hornworm)

Maruca testulalis (bean pod borer)

Melanolophia imitata

Mesographe forficalis

Mocis repanda (Mocis: semilooper)

Molippa sabina

Monema flavescens

Mythimna (Pseudaletia) unipuncta (armyworm)

Nephantis serinopa

Noctua (Triphaena) pronuba

Nomophila noctuella (lucerne moth)

Nymphalis antiopa (mourning-cloak butterfly)

Oiketicus moyanoi

Ommatopteryx texana

Operophtera brumata (winter moth)

Opsophanes sp.

O. fagata

Orgyia (Hemerocampa) antiqua (rusty tussock moth)

O. leucostigma (white-marked tussock moth)

O. (H.) pseudotsugata (Douglas-fir tussock moth)

O. thyellina

Orthosia gothica

Ostrinia (Pyrausta) nubilalis (European corn borer)

Paleacrita vernata (spring cankerworm)

Paulmnene juliana

Pandemis dumetana

P. pyrusana

Panolis flamnea

Papilio cresphontes (orange dog)

P. demoleus

P. philenor

Paralipsa (Aphemia) gularis

Paralobesia viteana

Paramyelois transitella

Parnara guttata

Pectinophora gossypiella (pink bollworm)

Pericallia ricini

Peridroma saucia (variegated cutworm)

Phalera bucephala

Phlogophora meticulosa

Phryganidia californica (California oakworm)

Phthorimaea (=Gnorimoschema) operculella (potato tuberworm)

Phyllonorycter (Lithocolletis) blancardella (spotted tentiformleafminer)

Pieris brassicae (large white butterfly)

P. canidia sordida

P. rapae (imported cabbageworm, small white butterfly)

Plathypena scabra (green cloverworm)

Platynota sp.

P. stultana

Platyptilia carduidactyla (artichoke plume moth)

Plodia interpunctella (Indian-meal moth)

Plutella xylostella as maculipennis (diamondback moth)

Prays citri (citrus flower moth)

P. oleae (olive moth)

Pseudoplusia includens (soybean looper)

Pygaera anastomosis

Rachiplusia ou

Rhyacionia buoliana (European pine shoot moth)

Sabulodes caberata (omnivorous looper)

Samia cynthia (cynthia moth)

Saturnia pavonia

Schizura concinna (red-humped caterpillar)

Schoenobius bipunctifer

Selenephera lunigera

Sesamia inferens

Sibine apicalis

Sitotroga cerealella (Angoumois grain moth)

Sparganothis pilleriana

Spilonota (Tmetocera) ocellana (eye-spotted budmoth)

Spilosoma lubricipeda (as menthastri)

S. virginica (yellow woollybear)

Spilosoma sp.

Spodoptera (Prodenia) eridania (southern armyworm)

S. exigua (beet armyworm, lucerne caterpillar)

S. frugiperda (fall armyworm)

S. littoralis (cotton leafworm)

S. litura

S. mauritia (lawn armyworm)

S. (P.) ornithogalli (yellow-striped armyworm)

S. (P.) praefica (western yellowstriped armyworm)

Syllepte derogata

S. silicalis

Symmerista canicosta

Thaumetopoea pityocampa (pine processionary caterpillar)

T. processionea

T. wauaria (currant webworm)

T. wilkinsoni

Thymelicus lineola (European skipper)

Thyridopteryx ephemeraeformis (bagworm)

Tineola bisselliella (webbing clothes moth)

Tortrix viridana (oak tortricid)

Trichoplusia ni (cabbage looper)

Udea profundalis (false celery leaftier)

U. rubigalis (celery leaftier, greenhouse leaftier)

Vanessa cardui (painted-lady)

V. io

Xanthopastis timais

Xestia (Amathes, Agrotis) c-nigrum (spotted cutworm)

Yponomeuta cognatella (=Y. evonymi) (Yponomeuta=Hyponomeuta)

Y. evonymella

Y. mahalebella

Y. malinella (small ermine moth)

Y. padella (small ermine moth)

Y. rorrella

Zeiraphera diniana

MALLOPHAGA

Bovicola bovis (cattle biting louse)

B. crassipes (Angora goat biting louse)

B. limbata

B. ovis (sheep biting louse)

Lipeurus caponis (wing louse)

Menacnathus stramineus (chicken body louse)

Menopon gallinae (shaft louse)

TRICHOPTERA

Hydropsyche pellucida

Potamophylax rotundipennis

TABLE 2 Plants recommended for protection by B. thuringinensisinsecticidal protein alfalfa escarole potatoes almonds field cornradishes apples filberts rangeland artichokes flowers raspberriesavocados forage crops safflower bananas forest trees shade trees beansfruit trees shingiku beets garlic small grains blackberries grapessoybeans blueberries hay spinach broccoli kale squash brussels sproutskiwi stonefruits cabbage kohlrabi stored corn caneberries lentils storedgrains carrots lettuce stored oilseeds cauliflower melons stored peanutscelery mint stored soybeans chard mustard greens stored tobacco cherriesnectarines strawberries chinese cabbage onions sugarbeets chrysanthemumsoranges sugar maple citrus ornamental trees sunflower collards parsleysweet corn cos lettuce pasture sweet potatoes cotton peaches tobaccocranberries peanuts tomatoes crop seed pears turf cucumbers peas turnipgreens currants pecans walnuts dewberries peppers watermelons eggplantpome fruit endive pomegranite

TABLE 3

Varieties of B. thuringiensis

alesti

aizawai

canadensis

dakota

dartnstadiensis

dendrolimus

entomocidus

finitimus

fowleri

galleriae

indiana

israelensis

kenyae

kurstaki

kyushuensis

morrisoni

ostriniae

pakistani

sotto

thompsoni

thuringiensis

tolworthi

toumanoffi

wuhanensis

TABLE 4 Predicted Determined Determined No. of nucleotides mol. wt. ofmol. wt. (kD), mol. wt. (kD), Relative^((A)) Plasmid in coding sequenceproduct (D) E. coli extracts mini-cells Toxicity pBt73-16 3537 133,344130/68 130/68 100 pBt73-10 2825 106,340 68 104/68 6 pBt73-3(Ava) 1836 68,591 68 68 6 pBt73-498 1428  53,981 45 50 0 ^((A))Based on acomparison of LD₅₀ values for E. coli extracts assayed against M. sextalarvae. Extracts of E. coli HB101 (pBt73-16) equal 100 by definition.

What is claimed is:
 1. A cell containing a recombinant DNA moleculecomprising a DNA segment encoding a partial Bacillus thuringiensis8-endotoxin protoxin, the partial protoxin encoding sequence beingsufficient to encode a complete toxin, said partial protoxin encodingsequence being terminated by DNA naturally functional in a eukaryoticcell comprising a stop codon in frame and a polyadenylation site 3′ tothe stop codon.